Projections of Alpine Snow-Cover in a High-Resolution Climate Simulation
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atmosphere Article Projections of Alpine Snow-Cover in a High-Resolution Climate Simulation Samuel Lüthi 1 , Nikolina Ban 1,*,† , Sven Kotlarski 2 , Christian R. Steger 1 , Tobias Jonas 3 and Christoph Schär 1 1 Institute for Atmospheric and Climate Sciences, ETH Zürich, 8006 Zurich, Switzerland 2 Federal Office of Meteorology and Climatology, MeteoSwiss, 8058 Zurich Airport, Switzerland 3 WSL Institute for Snow and Avalanche Research SLF, 7260 Davos, Switzerland * Correspondence: [email protected]; Tel.: +41-44-632-6672 † Current address: Universitaetsstr. 16, 8092 Zürich, Switzerland. Received: 15 July 2019; Accepted: 1 August 2019; Published: 13 August 2019 Abstract: The recent development of high-resolution climate models offers a promising approach in improving the simulation of precipitation, clouds and temperature. However, higher grid spacing is also a promising feature to improve the simulation of snow cover. In particular, it provides a refined representation of topography and allows for an explicit simulation of convective precipitation processes. In this study we analyze the snow cover in a set of decade-long high-resolution climate simulation with horizontal grid spacing of 2.2 km over the greater Alpine region. Results are compared against observations and lower resolution models (12 and 50 km), which use parameterized convection. The simulations are integrated using the COSMO (Consortium for Small-Scale Modeling) model. The evaluation of snow water equivalent (SWE) in the simulation of present-day climate, driven by the ERA-Interim reanalysis, against an observational dataset, reveals that the high-resolution simulation clearly outperforms simulations with grid spacing of 12 and 50 km. The latter simulations underestimate the cumulative amount of SWE over Switzerland over the whole annual cycle by 33% (12 km simulation) and 56% (50 km simulation) while the high-resolution simulation shows a spatially and temporally averaged difference of less than 1%. Scenario simulations driven by GCM MPI-ESM-LR (2081–2090 RCP8.5 vs. 1991–2000) reveal a strong decrease of SWE over the Alps, consistent with previous studies. Previous studies had found that the relative decrease becomes gradually smaller with elevation, but this finding was limited to low and intermediate altitudes (as a 12 km simulation resolves the topography up to 2500 m). In the current study we find that the height gradient reverses sign, and relative reductions in snow cover increases above 3000 m asl, where important parts of the cryosphere are present. In addition, the simulations project a transition from permanent to seasonal snow cover at high altitudes, with potentially important impacts to Alpine permafrost. This transition and the more pronounced decline of SWE emphasize the value of the higher grid spacing. Overall, we show that high-resolution climate models offer a promising approach in improving the simulation of snow cover in Alpine terrain. Keywords: snow water equivalent; snow cover; convection-resolving; climate projections 1. Introduction Snow cover in the Northern Hemisphere has significantly decreased since the middle of the 20th century [1]. This decrease was around 1.6% per decade for March and April and 11.7% for June over the period from 1967–2012. Also, permafrost temperatures have been increasing in most regions of the Northern Hemisphere since the 1980s, which led to reductions in permafrost thickness and spatial extent [1]. This trend is projected to further increase [1]. Consistent with these hemispheric trends, Atmosphere 2019, 10, 463; doi:10.3390/atmos10080463 www.mdpi.com/journal/atmosphere Atmosphere 2019, 10, 463 2 of 18 Alpine snow cover showed marked decreases. Even though snow depth, duration of continuous snow cover, and number of snowfall days increased gradually from the 1930s until the early 1980s, these indicators significantly decreased towards the end of the century [2]. This observed reduction can be attributed to the increased temperature since changes in precipitation remained rather small [3]. This trend is more pronounced at lower elevations, where winter temperatures are generally closer to the melting point. By the end of the century, Alpine snow volumes are projected to drop by 90%, 50%, and 30% for altitudes of 1000 m, 2000 m, and 3000 m, respectively [4]. In a recent study using an ensemble of regional climate models (RCMs), results show a reduction of 40–80% by mid-century for sites below 1500 m under an SRES A1B emission scenario [5]. For elevations between 2000–2500 m, reductions amount to 10–60% by mid-century and 30–80% by the end of the century, depending upon the model considered. This decrease leads to strong changes in the Alpine snow climate and poses major ecological and socio-economic challenges. Snow cover is an important part of the Alpine climate system as it alters surface energy fluxes by isolating the underlying ground through its comparably low thermal conductivity. More importantly, it increases the surface albedo which cools the surface by backscattering shortwave radiation. This highly non-linear snow-albedo feedback is one of the most important positive feedbacks in the climate system [6]. For ecology, snow cover is essential as not only the seasonal vegetation cycle but also hibernating animals depend strongly on the timing of the snow season [7]. Especially in the Alps, snow cover plays also a major economic role. Factors such as the length of the snow season or the snow reliability are crucial for the profitability of Alpine tourist destinations [8]. Moreover, snow functions as a key storage of water for hydropower, which accounts for more than half of the Swiss electricity production [9]. As an additional effect, declining snow cover and melting of permafrost can lead to new areas being affected by landslides and rock-fall hazards [10]. Thanks to the increase in the computational power in recent years, high-resolution regional climate models—models with horizontal resolutions of 1–4 km—are being used for climate change simulations [11–14]. The higher resolution allows to switch off the parametrization for convection, thereby enabling an improved representation of clouds and moist convection. In addition, higher resolution allows a better representation of complex mountainous topography. This aspect is especially promising for the simulation of snow, as previous studies concluded that the capability of climate models in simulating snow cover is considerably limited due to their horizontal resolution [5,15,16]. A higher resolution allows to better capture topographically influenced processes, such as winter inversions and cold air pools that are relevant for snow preservation. In the Alps, a higher grid spacing also allows to represent elevation levels above 3000 m, nearly up to 4000 m. This is a major advantage, as the climate change impact on the cryosphere depends considerably on surface elevation [17], and substantial parts of snow, permafrost and glaciers are present at high elevations. Up to now, most of the studies using high-resolution models focused on precipitation and clouds, and little research was conducted for snow, especially over Europe. Based on these identified gaps, we here address the following research questions: • Do kilometer–scale regional climate simulations provide an added value in terms of snow cover representation in Alpine terrain? • How is Alpine snow cover expected to change by the end of the 21st century based on high resolution regional climate simulations? To answer these questions, we use the set of simulations presented in [11,12] and previously analyzed for precipitation, but not for snow. The following section gives an overview of data sets and the different model runs. In Section 3.1 we are assessing the added value of higher horizontal resolution in simulating snow by comparing observational data of snow water equivalents (SWE) against three runs of the same model using different grid spacings (2.2 km, 12 km, and 50 km). In Section 3.2, we analyze the climate change signal of Alpine SWE, snowfall and temperatures and we assess the influence of horizontal grid spacing. Finally, we discuss our results in Section 3.4 and conclude the study in Section4. Atmosphere 2019, 10, 463 3 of 18 2. Data and Methods 2.1. Model Data The model data utilised for this study encompasses output from several existing simulations of the non-hydrostatic COSMO model (Consortium for Small-Scale Modeling) [18–20]. Details of the model set-up may be looked up in Ban et al. [11] while here only a brief overview of the main features is presented. The COSMO model is designed for limited-area weather forecasts and for regional climate simulations (i.e., for the application as an RCM) at horizontal resolutions from 0.5 to 200 km. The small grid scale of the 2.2 km resolution allows to resolve deep convection explicitly. In the 12 km and the 50 km model experiment, convection is parameterized using the Tiedtke mass-flux scheme with moisture convergence closure [21]. Time steps of 90 and 300 s are applied for the 12 and the 50 km simulation, respectively, while for the 2.2 km simulation a temporal discretization of 20 s is used. The model is horizontally discretized on a rotated latitude-longitude grid. Vertically, a pressure-based hybrid coordinate with 60 levels is used (40 levels for the 50 km simulation). The levels range from the surface to the top of the atmosphere at 20 hPa and have a vertical grid spacing from 20 m near the surface up to 1.2 km at the top. In the COSMO model, snow is represented as a single layer whose mass budget is determined by snowfall, sublimation, runoff and soil infiltration. Drifting snow, which leads to lateral redistribution and typically enhances sublimation, is not considered in the model. Likewise, retention of surface meltwater or rainfall within the snowpack by refreezing or as irreducible water in temperate snow is neglected.